NEEDLELESS INJECTION DEVICE HAVING A GEL AND A MEMBRANE

Abstract

The invention relates to a needleless injection device, comprising a firing chamber (11) for the needleless injection of a substance (25), having a firing chamber containing a pyrotechnic material and a gel-like medium, with which a substance, in particular an active substance, can be accelerated at high speed and injected in a needleless manner into a tissue or into a body by means of a membrane (15).

The invention also relates to a method for producing a needleless injection device of this type containing a firing chamber together with pyrotechnic material and filled with a gel-like medium, and use thereof.

Claims

1.-18. (canceled)

19. A needleless injection device comprising a chamber (11) containing a) at least one pyrotechnic material (24a) and b) at least one gel-like medium (24b), wherein the chamber (11) has at least one membrane (15) at a discharge opening and is provided with a substance application (25).

20. The needleless injection device according to claim 19, wherein the gel-like medium is selected from the group of gel, oleogel, lipogel, paraffin gel, and silicone oleogel.

21. The needleless injection device according to claim 19, wherein the gel-like medium is gas-free.

22. The needleless injection device according to claim 19, wherein the gel-like medium consists of a gelling agent and a liquid, in particular hydrophobic liquid.

23. The needleless injection device according to claim 22, wherein the gelling agent is an organic or inorganic gelling agent, in particular selected from the group of pectin, tragacanth, polyacrylic acids, polyvinylpyrrolidone, silicon dioxide, highly dispersed silicon dioxide, carboxymethylcellulose, carbomers (polyacrylic acid), cellulose ethers, poloxamers.

24. The needleless injection device according to claim 22, wherein the hydrophobic liquid is selected from the group of vegetable or animal oils, triglycerides, mono- and diglycerides, phospholipids, liquid waxes, alcohols, silicone oils, and paraffins.

25. The needleless injection device according to claim 19, wherein the chamber (11) is completely filled with a gel-like medium (24).

26. The needleless injection device according to claim 19, wherein the membrane (15) consists of steel, plastics, preferably titanium or sheet titanium.

27. The needleless injection device according to claim 19, wherein the membrane (15) has a thickness of from 0.1 mm to 0.6 mm.

28. The needleless injection device according to claim 19, wherein the firing-chamber-side membrane (13) leads into the combustion chamber (24).

29. The needleless injection device according to claim 19, wherein the membrane is formed as a multi-layered or double membrane, consisting of an inner membrane (13) and a skin-side membrane (15).

30. The needleless injection device according to claim 19, wherein the membrane is formed as a multi-layered or double membrane, consisting of an inner membrane (13) and a skin-side membrane (15), and the inner membrane (13) has a distance from the skin-side membrane (15) of from 0.2 mm to 1.0 mm or 1.5 mm.

31. The needleless injection device according to claim 30, wherein the distance is provided by means of a spacer (14) between the two membranes.

32. The needleless injection device according to claim 19, wherein at least one membrane (13) or (15) is curved.

33. The needleless injection device according to claim 19, containing an attachment (17) and/or support disc (16), characterised in that a distance of at least 5 mm is achieved between the skin (18) and the membrane (15).

34. The needleless injection device according to claim 19, wherein an activation unit (1, 2, 3, 4, 5, 6, 7, 8, 9, 10) is provided in the axial direction relative to the membrane (15).

35. The needleless injection device according to claim 19 for use of a medium or an active substance or medicinal product for needle-free application.

36. A method for producing a needleless injection device according to claim 19, wherein the chamber (11) is loaded with a gel-like medium (24b), and in particular the chamber (11) is completely filled with a gel-like medium (24b).

Description

[0054] The following examples and drawings are intended to explain the invention in greater detail, but without limiting the invention thereto.

[0055] FIG. 1 shows a cross-section of the injection device according to the invention with fixed membrane.

[0056] FIG. 2 shows the individual parts of the injection device according to the invention.

EXAMPLE 1

[0057] Production of bubble-free silicone oleogels having a low air content for the direct filling of the needleless injection device according to the invention.

[0058] Silicone Oils [0059] Silicone oil (100 cSt) from Sigma-Aldrich (Sigma-Aldrich, Taufkirchen, Germany) [0060] Silicone oil (500 cSt) from Sigma-Aldrich. (Sigma-Aldrich, Taufkirchen, Germany) [0061] Silicone oil (1000 cSt.) from Sigma-Aldrich (Sigma-Aldrich, Taufkirchen, Germany)

[0062] Highly Dispersed Silicon Dioxide [0063] Aerosil R200 Pharma (Evonik, Hanau-Wolfgang, Germany) [0064] Aerosil R972 Pharma (Evonik, Hanau-Wolfgang, Germany) [0065] Luer syringe (Norm-Ject) (Henke Sass Wolf, Tuttlingen, Germany) [0066] Luer adapter (Combifix Adapter) (B. Braun, Melsungen, Germany) [0067] Luer stopper (Combi-Stopper) (B. Braun, Melsungen, Germany) [0068] vacuum drying cabinet (Memmert, Schwabach, Germany)

[0069] Method:

[0070] The plunger of a Luer syringe is removed and the Luer opening is closed by a Luer stopper. The weighed amount of Aerosil is inserted into the Luer syringe from the opening (plunger-side). Depending on the sought concentration, various amounts of Aerosil are weighed in: (4% (m/m), 5% (m/m), 6% (m/m), 10% (m/m). The plunger of the syringe is carefully inserted back into the Luer Lock syringe without severely compromising the Aerosil. The Luer stopper is removed and is replaced by a Luer adapter. A further Luer syringe is connected to the Luer adapter with previously removed plunger. The two connected syringes are secured to a support. The weighed amount of silicone oil (m/m) is poured into the second, empty Luer syringe. The Aerosil is thus combined in the lower Luer syringe with the silicone oil in the upper Luer syringe by means of the Luer adapter.

[0071] The connected and filled syringes are placed in a vacuum drying cabinet and are deaerated for at least 4 hours at 10 mbar pressure. Here, the air escapes from the Aerosil and the silicone oil. Due to the adjustment to normal atmosphere, the silicone oil is pushed into the lower Luer syringe chamber containing Aerosil and little air. The silicone oil mixes with the Aerosil and at the same time prevents the infiltration of air into the mixture. The empty upper Luer syringe is removed. A new Luer syringe is connected to the Luer adapter. However, care must be taken to ensure that the Luer adapter is filled up to the edge with the viscous mixture in order to avoid air inclusions by the connection of the new syringe. The silicone oil and Aerosil mixture is pushed 20 times through the Luer adapter into the connected syringe for homogenisation. The Luer syringe and Luer adapter are then removed and the resultant silicone oleogel is closed in the syringe using a Luer stopper. The silicone oleogel can be used directly for the application after the mixing. The gel disposed in the syringe is metered via the Luer cone into the device according to the invention or the firing chamber disposed there by moving the plunger in accordance with the usual function of the syringe.

EXAMPLE 2

[0072] Determination of the Viscosity of the Silicone Oleogels

[0073] Materials [0074] Silicone oleogels are produced in accordance with the provisions according to Example 1.—4%, 5%, 6% silicone oleogels with Aerosil R200 Pharma [0075] 4%, 5%, 6%, 10% silicone oleogels with Aerosil R972 Pharma

[0076] Equipment [0077] Rheometer MCR100 from Anton Pear (Anton Pear, Graz, Austria) [0078] Plate PP50 (Diameter: 49.958 mm) [0079] Working gap 500 μm [0080] Measurement temperature: 250 C [0081] Measurement method: Rising shear rate of 1-100 s−1

[0082] A sufficient amount of the oleogel to be examined is applied to the working surface of the rheometer. The plate height is adjusted and any leaking, excess oleogel is carefully removed. A measurement is taken with rising shear rate.—At a shear rate of 36 s.sup.−1, the following viscosities were determined:

TABLE-US-00001 TABLE 1 Viscosities of the silicone oleogels at a shear rate of 36 s.sup.−1 Silicone oleoge Viscosity [Pa s] 4% Silicone oleogel (R200 Pharma)  8.3 ± 0.43 5% Silicone oleogel (R200 Pharma)  13.5 ± 0.68 6% Silicone oleogel (R200 Pharma)  19.2 ± 1.65 4% Silicone oleogel (R972 Pharma) 303.5 ± 8.7  5% Silicone oleogel (R972 Pharma) 450.7 ± 37.9 6% Silicone oleogel (R972 Pharma) 560.7 ± 38.4 10% Silicone oleogel (R972 Pharma) 1645.0 ± 161.3

KEY

[0083] 1 trigger, button [0084] 2 trigger housing [0085] 3 battery [0086] 4 spring cap [0087] 5 contact pin [0088] 6 contact spring [0089] 7 slotted nut [0090] 8 holder for glass feedthrough [0091] 9 feedthrough of the connections of the EED [0092] 10 EED (detonator) [0093] 11 firing chamber or chamber [0094] 12 O-ring seal of the firing chamber (can also be omitted in some embodiments of the device) [0095] 13 inner membrane or firing-chamber-side membrane [0096] 14 spacer, also performs sealing functions [0097] 15 skin-side membrane, fixed to membrane (13) and spacer (14) [0098] 16 support disc [0099] 17 attachment [0100] 18 skin or surface to be penetrated (bears against 17, not shown) [0101] 19 thread for ground connection screw (can also be omitted in some embodiments of the device) [0102] 20 firing chamber vent [0103] 21 cover, vent [0104] 22 housing for the parts 7-21 [0105] 23 guide for contact pin [0106] 24 firing chamber or combustion chamber (24) containing a pyrotechnic substance (24a) and a gel-like medium (24b) [0107] 25 substance application in the direction of the tissue or skin